Aluminum alloy housing and preparation method thereof

ABSTRACT

This disclosure provides an aluminum alloy housing and a preparation method for same. An external surface of the aluminum alloy housing has a convex portion and a concave portion, the convex portion has a convex oxide film and a convex electrophoretic decorative layer in turn, the concave portion has a concave oxide film or a concave electrophoretic decorative layer, surface of the convex electrophoretic decorative layer has a glossiness of 90-105, and surface of the concave oxide film has a glossiness of 5-25 or surface of the concave electrophoretic decorative layer has a glossiness of 0.5-5.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of International Application No. PCT/CN2016/111568, filed on Dec. 22, 2016, which is based on and claims priority to and benefits of Chinese Patent Application No. 201511019773.5, filed with the State Intellectual Property Office (SIPO) of the People's Republic of China on Dec. 30, 2015. The entire contents of the above referenced applications are hereby incorporated by reference.

TECHNICAL FIELD

The present disclosure relates to the field of electronic product technologies, and in particular, to an aluminum alloy housing and a preparation method for same.

BACKGROUND

With the development of electronic technologies, increasingly more electronic products appear in our life, for example, mobile phones, tablet computers, and e-readers. Most of these electronic products use plastic casings. However, as people have higher requirements on the quality of the electronic products, more and more electronic products use metal casings. On one hand, metal casings have better protection effects than plastic casings. On the other hand, the unique metal texture is also an important reason why the metal casings are becoming more popular.

Currently, surface treatment performed on a metal casing of an electronic product is mainly for the purpose of decorative and protective effects. In the existing method of performing surface treatment on a metal casing, anodic oxidation, micro-arc oxidation, and hard anodic oxidation on the surface of the metal casing can all achieve the foregoing two effects. However, in terms of the decorative effect, the metal casing after the treatment lacks diversity in appearance decoration and textures.

Therefore, to improve the diversity in appearance decoration and textures of a metal casing, it is necessary to develop an aluminum alloy housing that has desirable appearance decoration and a solid texture, and a preparation method for same.

SUMMARY

In order to resolve the problem that a mobile phone housing in the prior art lacks diversity in appearance decoration and textures, the present disclosure is directed to provide an aluminum alloy housing and a preparation method for same. The aluminum alloy housing has a bumpy solid texture and has a glossy convex side and concave side.

In order to achieve the foregoing objective, the present disclosure provides an aluminum alloy housing. According to embodiments of the present disclosure, an external surface of the aluminum alloy housing has a convex portion and a concave portion, the convex portion has a convex oxide film and a convex electrophoretic decorative layer in turn, the concave portion has a concave oxide film or a concave electrophoretic decorative layer, surface of the convex electrophoretic decorative layer has a glossiness of 90-105, and surface of the concave oxide film has a glossiness of 5-25 or surface of the concave electrophoretic decorative layer has a glossiness of 0.5-5.

Preferably, a height difference between the convex portion and the concave portion is 0.05-0.2 mm.

Preferably, the convex oxide film and the concave oxide film have different colors.

The present disclosure further provides a preparation method for an aluminum alloy housing, which includes steps of:

step a: performing first anodic oxidation on the surface of the aluminum alloy housing substrate;

step b: forming a convex electrophoretic decorative layer on surface of the aluminum alloy housing substrate on which the first anodic oxidation has been performed via first electrophoretic treatment;

step c: performing mechanical polishing on the surface of the aluminum alloy housing substrate on which the first electrophoretic treatment has been performed;

step d: performing laser carving on a surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed, so as to obtain a texture pattern having a convex-concave effect on the surface of the aluminum alloy housing substrate;

step e: performing second electrophoretic treatment or second anodic oxidation or hard anodic oxidation or micro-arc oxidation on portion of the texture pattern on the surface of the aluminum alloy housing substrate.

Preferably, wherein the first anodic oxidation and/or the second anodic oxidation comprises performing pretreatment on the surface of the aluminum alloy housing substrate and then forming an anode film by anodic oxidation.

Preferably, the pretreatment comprises: performing alkali etching for 3-20 s at a temperature of 50-70° C. by using 50-60 g/L of sodium hydroxide, neutralizing for 10-20 s a temperature of 15-25° C. by using 200-300 ml/L of nitric acid, and performing chemical polishing for 5-20 s at a temperature of 90-95° C. by using a chemical polishing solution containing 650-750 ml/L of phosphoric acid and 350-250 ml/L of sulfuric acid.

Preferably, the anodic oxidation comprises oxidizing the surface of the aluminum alloy housing substrate for 15-50 min under an anode voltage of 13-17 V and at a temperature of 10-21° C. by using 190-200 g/L of sulfuric acid.

Preferably, the first electrophoretic treatment and/or the second electrophoretic treatment comprises electrophoresing for 1-3min under a voltage of 140-200 V and at a temperature of 28-32° C. by using an electrophoresing solution having a pH of 7-9.

Preferably, the hard anodic oxidation comprises oxidizing for 25-50 min under a temperature of 5-12° C. by using a hard anodic oxidation solution.

Preferably, the hard anodic oxidation solution includes 170-270 g/L of sulfuric acid and 8-20 g/L of oxalic acid.

Preferably, the micro-arc oxidation includes oxidizing for 40-100 min under a temperature of 20-30° C. by using a micro-arc oxidation solution.

Preferably, the micro-arc oxidation solution includes 0.02-0.05 mol/L of sodium silicate and 0.03-0.07 mol/L of sodium hydroxide.

With the foregoing technical solution, first anodic oxidation is firstly performed on the surface of the aluminum alloy housing substrate, then a convex electrophoretic decorative layer is formed via first electrophoretic treatment, and then mechanical polishing is performed on the surface of the aluminum alloy housing substrate on which the first electrophoretic treatment has been performed, then a texture pattern having a convex-concave effect on the surface of the aluminum alloy housing substrate is formed via laser carving, next, second electrophoretic treatment or second anodic oxidation or hard anodic oxidation or micro-arc oxidation is performed on portion of the texture pattern on the surface of the aluminum alloy housing substrate, thereby producing an aluminum alloy housing having a bumpy solid texture and having a glossy convex side and non-glossy concave side.

The additional aspects and advantages of the present disclosure will be provided in the following description, and some of the additional aspects and advantages will become clear in the following description or be understood through practice of the present disclosure.

DETAILED DESCRIPTION

Specific implementations of the present disclosure are described in detail below. It should be understood that the specific implementations described herein are merely used for illustrating the present disclosure rather than limiting the present disclosure.

An aluminum alloy housing is provided according to an embodiment of the present disclosure. An external surface of the aluminum alloy housing has a convex portion and a concave portion, the convex portion has a convex oxide film and a convex electrophoretic decorative layer in turn, the concave portion has a concave oxide film or a concave electrophoretic decorative layer, surface of the convex electrophoretic decorative layer has a glossiness of 90-105, and surface of the concave oxide film has a glossiness of 5-25 or surface of the concave electrophoretic decorative layer has a glossiness of 0.5-5. By forming a convex portion and a concave portion on the external surface of the aluminum alloy housing, the aluminum alloy housing can have a bumpy solid texture. In addition, by polishing the convex oxide film formed on the surfaces of the convex portion, the surfaces of the convex oxide film are glossy. In the present disclosure, the glossiness means how close the surface of the oxide film is to a mirror surface, and can be measured by using a method commonly known in the field, for example, measured by using a gloss meter.

In the present disclosure, a method for forming a convex portion and a concave portion on the external surface of the aluminum alloy housing, and a method for forming a convex oxide film on the convex portion and forming a concave oxide film on the concave portion will be described in the following preparation method for the aluminum alloy housing.

In the preparation method for the aluminum alloy housing according to an embodiment of the present disclosure, preferably, the convex oxide film and the concave oxide film are of different colors. By making the convex oxide film and the concave oxide film have different colors, the aluminum alloy housing has film layers of different colors.

A preparation method for an aluminum alloy housing according to an embodiment of the present disclosure sequentially includes:

step a: performing first anodic oxidation on the surface of the aluminum alloy housing substrate;

step b: forming a convex electrophoretic decorative layer on surface of the aluminum alloy housing substrate on which the first anodic oxidation has been performed via first electrophoretic treatment;

step c: performing mechanical polishing on the surface of the aluminum alloy housing substrate on which the first electrophoretic treatment has been performed;

step d: performing laser carving on a surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed, so as to obtain a texture pattern having a convex-concave effect on the surface of the aluminum alloy housing substrate;

step e: performing second electrophoretic treatment or second anodic oxidation or hard anodic oxidation or micro-arc oxidation on portion of the texture pattern on the surface of the aluminum alloy housing substrate.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, in order to obtain a glossy effect of the aluminum alloy housing, mechanical polishing is performed on the surface of the aluminum alloy housing substrate on which the first electrophoretic treatment has been performed. The anodic oxidation film layer on the surface of the aluminum alloy housing substrate is polished by using a mechanical polishing machine, to reduce the overall thickness of the anodic oxidation film layer by approximately 2 μm, so that the surface of the anodic oxidation film is glossy and can reflect light, and a glossy surface having a high glossiness is formed, and then laser carving is performed so as to obtain a convex-concave difference on surface of the aluminum alloy housing substrate, thus to obtain a bumpy solid texture.

The aluminum alloy housing substrate used in the present disclosure is not particularly limited. Various aluminum alloy housing bodies can be used, for example, a product of industrial standard 1000-7000 series, a die-casting aluminum alloy, and a pressure-casting aluminum alloy. The aluminum alloy housing substrate in the present disclosure is an aluminum alloy housing body of various shapes and structures that are commonly used by a person skilled in the art, and is not particularly limited in the present disclosure. The various shapes and structures of the aluminum alloy housing substrate can be accomplished by mechanical processing. The aluminum alloy housing can be used as a housing of a mobile phone, a tablet computer, an e-reader, or the like.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, in step a, before first anodic oxidation is performed on the surface of the aluminum alloy housing substrate, blasting and drawing treatment can be performed on the surface of the aluminum alloy housing substrate in advance. In the present disclosure, the blasting can be performed by using a method commonly known in the field. For example, after the surface of the aluminum alloy housing substrate is sanded by using a sander, blasting treatment is performed on the surface of the aluminum alloy housing substrate by using a ceramic sand of 80-400 meshes under a pressure of 0.1-0.24 MPa, so that the surface of the aluminum alloy housing substrate feels sandy. The drawing treatment can be performed by using a method commonly known in the field. For example, the surface of the aluminum alloy housing substrate can be drawn by a drawing machine with No. 400 to No. 1200 drawing wheels to achieve the required brushed texture from coarse to fine.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, preferably, the first anodic oxidation and/or the second anodic oxidation may include performing pretreatment on the surface of the aluminum alloy housing substrate and then forming an anode film by anodic oxidation. There is no special requirement on the thickness of the formed anode film, and the thickness is usually 6-10 μm.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, preferably, the pretreatment is performed to make the surface of the aluminum alloy housing substrate clean and ensure that a uniform anode film is formed on the surface of the aluminum alloy housing substrate by anodic oxidation. The pretreatment may include: performing alkali etching for 3-20 s at a temperature of 50-70° C. by using 50-60 g/L of sodium hydroxide, neutralizing for 10-20 s a temperature of 15-25° C. by using 200-300 ml/L of nitric acid, and performing chemical polishing for 5-20 s at a temperature of 90-95° C. by using a chemical polishing solution containing 650-750 ml/L of phosphoric acid and 350-250 ml/L of sulfuric acid.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, the method of the anodic oxidation can be an anodic oxidation method commonly known in the field. Preferably, the anodic oxidation may include oxidizing the surface of the aluminum alloy housing substrate for 15-50 min under an anode voltage of 13-17 V and at a temperature of 10-21° C. by using 190-200 g/L of sulfuric acid.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, an electrophoretic decorative layer is formed on surface of the aluminum alloy housing substrate via the first electrophoretic treatment and/or the second electrophoretic treatment, which may protect the aluminum alloy housing effectively and provide a decorative effect. The first electrophoretic treatment and/or the second electrophoretic treatment may include electrophoresing for 1-3min under a voltage of 140-200 V and at a temperature of 28-32° C. by using an electrophoresing solution having a pH of 7-9. The electrophoresing solution could be any electrophoresing solution commonly used in the art, as long as the electrophoretic decorative layer could be formed on surface of the aluminum alloy housing substrate. For example, the electrophoresing solution may contain a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, a texture pattern having a convex-concave effect on the surface of the aluminum alloy housing substrate could be obtained by laser carving a surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed. A method of the laser carving could be any method of laser carving commonly used in the art, for example, the laser carving may carried out through a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 m.

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, preferably, the hard anodic oxidation may include oxidizing for 25-50 min under a temperature of 5-12° C. by using a hard anodic oxidation solution. More preferably, the hard anodic oxidation solution may include 170-270 g/L of sulfuric acid and 8-20 g/L of oxalic acid. Electrical parameters of the hard anodic oxidation may include: forward square wave pulse, duty ratio of 60%-80%, frequency of 500-1000 Hz, electric current density of 3-7 A/dm².

In the preparation method for an aluminum alloy housing according to the embodiment of the present disclosure, preferably, the micro-arc oxidation may include oxidizing for 40-100 min under a temperature of 20-30° C. by using a micro-arc oxidation solution. More preferably, the micro-arc oxidation solution may include 0.02-0.05 mol/L of sodium silicate and 0.03-0.07 mol/L of sodium hydroxide. A oxidation forward voltage of the micro-arc oxidation may be 400-600 V.

The preparation method for an aluminum alloy housing according to the present disclosure is further described below by using exemplary embodiments. However, the present disclosure is not limited to the following exemplary embodiments.

Embodiment 1

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 15° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 90° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 15° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160 V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.05 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 15° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate, thereby obtaining the aluminum alloy housing of the present disclosure. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160 V, an electrophoresing time of 2 min, a pH of 7.8, using an electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan). The weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

Embodiment 2

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 70° C., the aluminum alloy housing substrate was subjected to alkali etching for 20 s in a sodium hydroxide aqueous solution with a concentration of 60 g/L, and was cleaned twice with deionized water. Then, at a temperature of 20° C., the aluminum alloy housing substrate was subjected to neutralization for 20 s in nitric acid with a concentration of 300 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 93° C., the aluminum alloy housing substrate was subjected to polishing for 20 s in a chemical polishing solution containing 700 ml/L of phosphoric acid and 300 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 20° C., the aluminum alloy housing substrate was subjected to neutralization for 20 s in nitric acid with a concentration of 300 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 195 g/L as a bath solution, an anode voltage being 17 V, a temperature being 10° C., and an oxidation time being 50 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 32° C., a voltage of 200 V, a electrophoresing time of 1 min, a pH of 7, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.2 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 7° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 20 s in a sodium hydroxide aqueous solution with a concentration of 60 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 300 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate, thereby obtaining the aluminum alloy housing of the present disclosure. Conditions of the electrophoretic treatment include: a temperature of 32° C., a voltage of 200 V, an electrophoresing time of 1 min, a pH of , using an electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan). The weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

Embodiment 3

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to anodic oxidation to form an anode film on a surface of the cleaned aluminum alloy housing substrate, thereby obtaining the aluminum alloy housing of the present disclosure. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 5 min.

Embodiment 4

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to hard anodic oxidation by using a hard anodic oxidation solution including 200 g/L of sulfuric acid and 15 g/L of oxalic acid for 25 min, under a temperature of 10° C. An electrical parameters of the hard anodic oxidation include: forward square wave pulse, duty ratio of 70%, frequency of 800 Hz, electric current density of 5 A/dm²; thereby obtaining the aluminum alloy housing of the present disclosure.

Embodiment 5

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to hard anodic oxidation by using a hard anodic oxidation solution including 170 g/L of sulfuric acid and 20 g/L of oxalic acid for 30 min, under a temperature of 5° C. An electrical parameters of the hard anodic oxidation include: forward square wave pulse, duty ratio of 80%, frequency of 500 Hz, electric current density of 3 A/dm²; thereby obtaining the aluminum alloy housing of the present disclosure.

Embodiment 6

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to hard anodic oxidation by using a hard anodic oxidation solution including 270 g/L of sulfuric acid and 20 g/L of oxalic acid for 25 min, under a temperature of 12° C. An electrical parameters of the hard anodic oxidation include: forward square wave pulse, duty ratio of 60%, frequency of 1000 Hz, electric current density of 7 A/dm²; thereby obtaining the aluminum alloy housing of the present disclosure.

Embodiment 7

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to micro-arc oxidation by using a micro-arc oxidation solution including 0.03 mol/L of sodium silicate and 0.05 mol/L of sodium hydroxide for 40 min, under a temperature of 25° C., and an oxidation forward voltage of 500 V; thereby obtaining the aluminum alloy housing of the present disclosure.

Embodiment 8

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to micro-arc oxidation by using a micro-arc oxidation solution including 0.02 mol/L of sodium silicate and 0.07 mol/L of sodium hydroxide for 100 min, under a temperature of 30° C., and an oxidation forward voltage of 400V; thereby obtaining the aluminum alloy housing of the present disclosure.

Embodiment 9

This embodiment is used to describe the aluminum alloy housing of the present disclosure and a preparation method for same.

A pressure-casting aluminum alloy rear housing substrate (purchased from BYD Co., Ltd.) for use in a P8-model mobile phone is used as an aluminum alloy housing substrate of the this embodiment.

At a temperature of 50° C., the aluminum alloy housing substrate was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, at a temperature of 95° C., the aluminum alloy housing substrate was subjected to polishing for 10 s in a chemical polishing solution containing 650 ml/L of phosphoric acid and 350 ml/L of sulfuric acid, and was cleaned twice with deionized water. Then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water. Next, the aluminum alloy housing substrate was dried for 20 min at a temperature of 80° C. in a drying oven, to obtain the cleaned and dried aluminum alloy housing substrate.

An anode film was formed on a surface of the cleaned and dried aluminum alloy housing substrate by anodic oxidation. Conditions of the anodic oxidation include: using sulfuric acid with a concentration of 190 g/L as a bath solution, an anode voltage being 15 V, a temperature being 19° C., and an oxidation time being 35 min.

The aluminum alloy housing substrate on which the anodic oxidation has been performed was subjected to electrophoretic treatment to form an electrophoretic decorative layer on surface of the aluminum alloy housing substrate. Conditions of the electrophoretic treatment include: a temperature of 30° C., a voltage of 160V, a electrophoresing time of 2 min, a pH of 7.8, using a electrophoresing solution containing a flat lacquer (WNO-1) of Shimizu Corporation (Japan) and a varnish (NNO-4) of Shimizu Corporation (Japan); the weight ratio of the flat lacquer to the varnish is 7:3, and a content of a solid composition in the electrophoresing solution is 13 wt %; the varnish (NNO-4) includes 50 wt % of acrylic resin, 6 wt % of 2-butoxy ethanol, 20 wt % of ethylene glycol monoisobutyl ether, 18 wt % of diethyl diol butyraldehyde, and 6 wt % of other composition; the flat lacquer (WNO-1) includes 50 wt % of acrylic resin, 10 wt % of 2-butoxy ethanol, and 40 wt % of other composition.

The electrophoretic decorative layer on the surface of the aluminum alloy housing substrate was polished by using a mechanical polishing machine, to reduce the overall thickness of the electrophoretic decorative layer by approximately 2 μm, so that the surface of the electrophoretic decorative layer is glossy and can reflect light.

The surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed was subjected to laser carving via a laser carving machine, so as to expose the aluminum alloy substrate and to obtain a texture pattern having a depth of 0.1 mm and a convex-concave effect on the surface of the aluminum alloy housing substrate.

Then, at a temperature of 50° C., the aluminum alloy housing substrate after being laser carved was subjected to alkali etching for 10 s in a sodium hydroxide aqueous solution with a concentration of 55 g/L, and was cleaned twice with deionized water, and then, at a temperature of 25° C., the aluminum alloy housing substrate was subjected to neutralization for 10 s in nitric acid with a concentration of 250 ml/L, and was cleaned twice with deionized water.

Then, the cleaned aluminum alloy housing substrate was subjected to micro-arc oxidation by using a micro-arc oxidation solution including 0.05 mol/L of sodium silicate and 0.03 mol/L of sodium hydroxide for 60 min, under a temperature of 20° C., and an oxidation forward voltage of 600 V; thereby obtaining the aluminum alloy housing of the present disclosure.

Performance Tests

Performance tests are performed, according to the following methods, on the aluminum alloy housings with clear convex-concave patterns obtained in Embodiments 1-9. Test results are as shown in Table 1.

Glossiness Test

A gloss meter (German BKY micro gloss meter A-4460) was used to test the glossiness of the surfaces of the aluminum alloy housings obtained in Embodiments 1-9. The results are as shown in Table 1.

Scratch Resistance Test

A UNI pen having 2H hardness was used to scratch at three different places of a sample with a force of 800 g applied at an angle of 45 degrees and a stroke of 10 mm. It is observed whether an evident scratch appears on the sample. If no, it indicates that the sample is qualified.

High Temperature Resistance Test

The sample was put into a precise high temperature test chamber (HOLINK HRHL45), was heated for 240 hours at a temperature of 85° C., and stayed for 2 hours at room temperature. It is observed whether fall-off, deformation, crack, and color change occurs in the appearance of the sample. If no, it indicates that the sample is qualified.

Low Temperature Resistance Test

The sample was put into a constant temperature and humidity test chamber (Taiwan KS ON, THS-2001), stayed for 240 hours at a temperature of −40° C., and then stayed for 2 hours at room temperature. It is observed whether fall-off, deformation, crack, and color change occurs in the appearance of the sample. If no, it indicates that the sample is qualified.

Moisture Resistance Test

The sample was put into a constant temperature and humidity test chamber (Taiwan KSON, HTS-400) with a humidity of 90% and a temperature of 60° C., stayed for 96 hours, and then stayed for 2 hours at room temperature. It is observed whether fall-off, deformation, crack, and color change occurs in the appearance of the sample. If no, it indicates that the sample is qualified.

Temperature Shock Test

The sample was put into a thermal shock test chamber (HOLINK HTS-400), and first stayed for 1 hour in an environment with a temperature of −40° C.; then, the temperature was switched to 85° C. (a switching time was 15 s), and the sample stayed for 1 hour at the temperature of 85° C. This process is repeated 12 times (24 hours). It is observed whether fall-off, deformation, crack, and color change occurs in the appearance of the sample. If no, it indicates that the sample is qualified. Salt spray test

The sample was put into a test chamber (HOLINK H-SST-90 salt spray tester) with a temperature of 30° C. and a humidity of 85% or higher. A solution with pH=6.8 (content of the solution: 50 g/L of NaCl) was used to spray continuously for 48 hours. Then, the sample was taken out, washed with normal-temperature water for 5 min, and dried with a drier. The sample stayed for 1 hour at room temperature. It is observed whether fall-off, deformation, crack, and color change occurs in the appearance of the sample. If no, it indicates that the sample is qualified.

TABLE 1 Performance Test Results of Aluminum Alloy Housings Obtained in Embodiments 1-9 Glossiness Glossiness Scratch High Low Temperature of convex of concave resistance temperature temperature Moisture shock Salt spray portion portion test test test test test test Embodiment 1 96.2 14.5 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 2 96.4 15.2 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 3 97.2 19.2 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 4 95.6 24.8 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 5 105.0 16.2 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 6 94.5 5.4 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 7 93.5 19.7 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 8 90.0 0.5 Qualified Qualified Qualified Qualified Qualified Qualified Embodiment 9 96.5 5.0 Qualified Qualified Qualified Qualified Qualified Qualified

It can be seen from the foregoing table that, the surface of the aluminum alloy housing of the present disclosure is not abraded easily, and the surface layer does not fall off easily, thereby improving the durability of the aluminum alloy housing. Moreover, with the convex-concave pattern, the aluminum alloy housing achieves a beautiful appearance effect, and has a clear bumpy solid texture. Therefore, the aluminum alloy housing provided by the present disclosure is beautiful and durable. In addition, after mechanical polishing, the surfaces of the aluminum alloy housings obtained in Embodiments 1-9 are also glossy.

In the description of the specification, the description made with reference to terms such as “one embodiment”, “some embodiments”, “example”, “specific example”, or “some examples” means that a specific characteristic, structure, material or feature described with reference to the embodiment or example is included in at least one embodiment or example of the present disclosure. In the specification, the illustrative expression of the foregoing terms is not necessarily intended for the same embodiment or example. Moreover, the described specific characteristic, structure, material or feature can be combined properly in any one or more embodiments or examples. In addition, without causing conflicts, a person skilled in the art can integrate and combine different embodiments or examples described in the specification or characteristics of different embodiments or examples.

Although the embodiments of the present disclosure have been shown and described above, it can be understood that the foregoing embodiments are merely examples and should not be construed as limitations on the present disclosure. A person of ordinary skill can make changes, modifications, replacements and transformations on the embodiments without departing from the scope of the present disclosure. 

What is claimed is:
 1. An aluminum alloy housing, comprising an external surface having a convex portion and a concave portion, wherein: the convex portion includes a convex oxide film and a convex electrophoretic decorative layer, wherein a surface of the convex electrophoretic decorative layer has a glossiness of 90-105; and the concave portion includes a concave oxide film or a concave electrophoretic decorative layer, wherein a surface of the concave oxide film has a glossiness of 5-25, and a surface of the concave electrophoretic decorative layer has a glossiness of 0.5-5.
 2. The aluminum alloy housing according to claim 1, wherein a height difference between the convex portion and the concave portion is 0.05-0.2 mm.
 3. The aluminum alloy housing according to claim 1, wherein the convex oxide film and the concave oxide film have different colors.
 4. A preparation method for an aluminum alloy housing, comprising steps of: step a: performing first anodic oxidation on a surface of an aluminum alloy housing substrate; step b: forming a convex electrophoretic decorative layer on a surface of the aluminum alloy housing substrate on which the first anodic oxidation has been performed via first electrophoretic treatment; step c: performing mechanical polishing on a surface of the aluminum alloy housing substrate on which the first electrophoretic treatment has been performed; step d: performing laser carving on a surface of the aluminum alloy housing substrate on which the mechanical polishing has been performed, so as to obtain a texture pattern having a convex-concave effect on the surface of the aluminum alloy housing substrate; step e: performing a process on portion of the texture pattern on the surface of the aluminum alloy housing substrate, wherein the process is selected from the group consisting of: second electrophoretic treatment, second anodic oxidation, hard anodic oxidation and micro-arc oxidation.
 5. The preparation method according to claim 4, wherein the first anodic oxidation or the second anodic oxidation comprises performing pretreatment on the surface of the aluminum alloy housing substrate and then forming an anode film by anodic oxidation.
 6. The preparation method according to claim 5, wherein the pretreatment comprises: performing alkali etching for 3-20 s at a temperature of 50-70° C. by using 50-60 g/L of sodium hydroxide, neutralizing for 10-20 s a temperature of 15-25° C. by using 200-300 ml/L of nitric acid, and performing chemical polishing for 5-20 s at a temperature of 90-95° C. by using a chemical polishing solution containing 650-750 ml/L of phosphoric acid and 350-250 ml/L of sulfuric acid.
 7. The preparation method according to claim 4, wherein the anodic oxidation comprises oxidizing the surface of the aluminum alloy housing substrate for 15-50 min under an anode voltage of 13-17 V and at a temperature of 10-21° C. by using 190-200 g/L of sulfuric acid.
 8. The preparation method according to claim 4, wherein the first electrophoretic treatment or the second electrophoretic treatment comprises electrophoresing for 1-3 min under a voltage of 140-200 V and at a temperature of 28-32° C. by using an electrophoresing solution having a pH of 7-9.
 9. The preparation method according to claim 4, wherein the hard anodic oxidation comprises oxidizing for 25-50 min under a temperature of 5-12° C. by using a hard anodic oxidation solution.
 10. The preparation method according to claim 4, wherein the hard anodic oxidation solution includes 170-270 g/L of sulfuric acid and 8-20 g/L of oxalic acid.
 11. The preparation method according to claim 4, wherein the micro-arc oxidation includes oxidizing for 40-100 min under a temperature of 20-30° C. by using a micro-arc oxidation solution.
 12. The preparation method according to claim 4, wherein the micro-arc oxidation solution includes 0.02-0.05 mol/L of sodium silicate and 0.03-0.07 mol/L of sodium hydroxide. 